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Abstract
Hamiltonian matrices in electronic and nuclear contexts are highly compute-intensive to calculate, mainly due to the cost for the potential matrix. Typically these matrices
contain many off-diagonal elements that are orders of magnitude smaller than diagonal elements. We illustrate that here for vibrational H-matrices for H2O, C2H3 (vinyl)
and C2H5NO2 (glycine) using full-dimensional ab initio-based potential surfaces. We then show that many of the these small elements can be replaced by zero with small
errors of the resulting full set of eigenvalues, depending on the threshold value for this replacement. As a result of this empirical evidence, we investigate three machine
learning approaches to predict the zero elements. This is shown to be successful for these H-matrices after training on a small set of calculated elements. For one vinyl
and glycine H-matrices, of order 15 552 and 8 828, respectively, training on a percent or so of elements is sufficient to obtain all eigenvalues with a mean absolute error of roughly 2 cm-1.
